KR20220170636A - Aerosol generatign device with wireless charging - Google Patents

Abstract

According to the present invention, provided is an aerosol generating device in which a heater provided in a holder is implemented using an induction heating method, and a battery of the holder inserted into a cradle can be wirelessly charged by using a coil for induction heating for wireless charging. The wirelessly rechargeable aerosol generating device according to an embodiment of the present invention comprises: a cradle having an insertion space into which the holder is inserted, a battery, and a TX coil connected to the battery; and a holder having an RX wireless charging block and inserted into the cradle to charge wireless power transmitted from the TX coil provided in the cradle. The holder includes: a chamber into which a stick can be inserted; a heater driving unit; an induction heating unit selectively connected to the heater driving unit and including a resonance capacitor and an induction coil; a susceptor inductively heated by the induction heating unit; a first switch block provided between the heater driving unit and the induction heating unit and between the RX wireless charging block and the induction heating unit to selectively switch; a resonance frequency adjustment means provided between the induction heating unit and the RX wireless charging block to adjust an induction heating resonance frequency to a wireless charging RX resonance frequency; a second switch block for selectively switching the connection between the induction heating unit, the resonance frequency adjustment means, and the RX wireless charging block; and a microcontroller which controls the heater driving unit and/or the first switch block and/or the second switch block.

Description

Wireless rechargeable aerosol generator {AEROSOL GENERATIGN DEVICE WITH WIRELESS CHARGING}

The present invention relates to an aerosol generator capable of wireless charging, and more particularly, to an aerosol generator capable of providing a configuration in which a heater is implemented in an induction heating method and a coil for induction heating is used for wireless charging.

Inhalation of an aerosol in the air, i.e., an aerosol, commonly referred to as smoking, can be achieved. In the past, cigarettes in the form of cigarettes were almost the only means of inhaling these preference substances, but recently, electronic cigarettes have also been established as another means. Electronic cigarettes vaporize the inhaled material into vapor by applying heat or ultrasonic waves to the cartridge containing the inhaled material in liquid form to generate an aerosol, which is completely different from conventional cigarettes that generate smoke by burning, It has the advantage of being able to prevent the generation of various harmful substances that may be generated by combustion, in particular. In addition, according to the demand of consumers who prefer cigarette-type conventional cigarettes, an electronic cigarette (stick) having a filter part of a conventional cigarette and a cigarette part in the shape of a cigarette has also been proposed. is vaporized by heating with an electronic heater to form an aerosol, and the user inhales the aerosol through a filter part of a stick having a configuration equivalent to that of a conventional cigarette. As an aerosol generating device for generating aerosol by heating a stick, a type divided into a holder and a cradle has been commercialized. The holder having a chamber into which the stick is inserted includes a heater, a control board, and a low-capacity battery, An insertion space into which the holder can be inserted is provided in the cradle containing a large-capacity battery capable of charging the low-capacity battery of the holder, and corresponding contact terminals are provided in the holder and the cradle, so that the holder is inserted into the insertion space of the cradle. After charging, power from the battery of the holder is applied to the heater to heat the stick inserted into the chamber of the holder to generate an aerosol. As a heater of the holder, a resistance heating type heater has been applied. However, the terminals formed to correspond to the holder and the cradle for charging can be problematic when exposed to moisture or moisture, and exposing the terminals is not good for aesthetics in design, and the heater of the holder is heated to the terminals in the process. There was a problem in that the temperature of the holder held by the user excessively increased due to heat transfer.

The present invention is to solve the problems of the prior art, to provide a specific configuration for charging the battery of the holder inserted into the cradle through wireless charging.

In addition, the present invention is to implement a heater in an induction heating method, but to provide a configuration in which a coil for induction heating is used for wireless charging.

In addition, the present invention is to provide a configuration capable of increasing wireless charging efficiency by converting an induction heating resonance frequency to a wireless charging RX resonance frequency during wireless charging.

According to the present invention, the heater provided in the holder is implemented in an induction heating method, but the coil for induction heating is used for wireless charging to provide an aerosol generator capable of wirelessly charging the battery of the holder inserted into the cradle. A wireless rechargeable aerosol generator according to an embodiment of the present invention includes a cradle having an insertion space into which a holder is inserted, a battery, and a TX coil connected to the battery; A holder having an RX wireless charging block and inserted into a cradle to charge wireless power transmitted from a TX coil provided in the cradle; including, but, the holder includes a chamber into which a stick can be inserted; a heater driver; an induction heating unit selectively connected to the heater driving unit and having a resonant capacitor and an induction coil; a susceptor induction heated by an induction heating unit; a first switch block provided between the heater driver and the induction heating unit and between the RX wireless charging block and the induction heating unit to be selectively switched; a resonant frequency adjusting means provided between the induction heating unit and the RX wireless charging block to adjust the induction heating resonant frequency to the wireless charging RX resonant frequency; a second switch block for selectively switching the connection between the induction heating unit, the resonant frequency adjusting unit, and the RX wireless charging block; and a microcontroller controlling the heater driver and/or the first switch block and/or the second switch block.

In addition, according to the embodiment, the resonant frequency adjusting unit is a resonant frequency adjusting induction coil that is connected to the RX wireless charging block and can be serially connected to the induction coil by a second switch block, where the second switch block controls the induction coil and the resonant frequency. It is provided between the induction coils.

In addition, according to the embodiment, the resonant frequency adjusting means is a resonant frequency adjusting capacitor that is connected in parallel with the resonant capacitor and can be connected to the RX wireless charging block by a second switch block, wherein the second switch is the resonant frequency adjusting capacitor and the RX wireless charging block. It is provided between, and between the induction coil and the RX wireless charging block, a third switch block that is turned on and off under the control of the microcontroller is included.

In addition, according to the embodiment, the resonant frequency control unit is connected to the RX wireless charging block and is connected in parallel to the resonant frequency control induction coil that can be connected in series to the induction coil by the second switch block, and to the resonance capacitor and is connected to the second switch block. The second switch block is a switch block provided between the induction coil and the resonance frequency control induction coil, and a switch provided between the resonance frequency control capacitor and the RX wireless charging block. contain each block.

In addition, according to the embodiment, the resonant frequency adjusting unit is a resonant frequency adjusting induction coil that is connected to the RX wireless charging block and can be connected in parallel to the induction coil by a second switch block, where the second switch block is connected to the induction coil and the RX wireless charging block. placed between blocks.

In addition, according to the embodiment, the resonant frequency adjusting means is a resonant frequency adjusting capacitor that is connected in series with the resonant capacitor and can be connected to the induction coil by a second switch block, wherein the second switch block is connected between the resonant capacitor and the induction coil and the resonant frequency It is provided between the adjusting capacitor and the induction coil, and between the induction coil and the RX wireless charging block, a third switch block that is turned on and off under the control of a microcontroller is included.

In addition, according to the embodiment, the resonant frequency control means is connected to the RX wireless charging block, is connected in series with the resonant frequency control induction coil that can be connected in parallel with the induction coil by the second switch block, and is connected in series with the resonance capacitor and is connected to the second switch block. The second switch block is provided between the switch block provided between the induction coil and the RX wireless charging block, between the resonance capacitor and the induction coil, and between the resonance frequency control capacitor and the induction coil. Each includes a switch block that

Also, according to an embodiment, the RX wireless charging block includes a rectifier circuit and a battery.

According to the present invention, an aerosol generator capable of wirelessly charging a battery of a holder inserted into a cradle by implementing a heater provided in a holder in an induction heating method and using an induction coil for wireless charging is provided.

According to the present invention, an induction coil for induction heating functions as an RX coil for wireless charging, and an aerosol generator capable of increasing wireless charging efficiency by converting the induction heating resonance frequency to the wireless charging RX resonance frequency during wireless charging Provides an aerosol generator .

1 schematically shows the configuration of a holder and a cradle according to the present invention.
2 is a circuit block diagram of a holder for wireless charging according to a first embodiment of the present invention.
3 is a circuit block diagram of a holder for wireless charging according to a second embodiment of the present invention.
4 is a circuit block diagram of a holder for wireless charging according to a third embodiment of the present invention.
5 is a circuit block diagram of a holder for wireless charging according to a fourth embodiment of the present invention.
6 is a circuit block diagram of a holder for wireless charging according to a fifth embodiment of the present invention.
7 is a circuit block diagram of a holder for wireless charging according to a sixth embodiment of the present invention.

Hereinafter, the present invention will be described based on the accompanying drawings and preferred embodiments.

1 schematically shows the configuration of a holder and a cradle according to the present invention. The holder 20 is provided with a chamber 21-1 into which a stick (not shown) can be inserted. When the stick is inserted into the chamber 21-1 and the aerosol forming material of the stick is heated by the heater of the holder 20, aerosol is generated and the user can inhale the aerosol through the filter provided at the top of the stick. These sticks have a shape similar to that of conventional cigarettes.

The holder 20 includes a small-capacity battery 22, a control board 23, and a heater. The heater of the holder 20 includes an induction coil L ₁ and a susceptor 21- that can be inserted into a stick. 2) is shown to be constituted by That is, the susceptor 21-2 is induction-heated by the induction coil L ₁ , and the induction-heated susceptor 21-2 heats the aerosol-forming material inside the stick to form an aerosol. As shown in the figure, the susceptor 21-2 may be configured in a blade or needle type, or may be formed in a trident shape.

Alternatively, the susceptor may be provided in a pipe shape forming a wall surface of the chamber 21-1 of the holder 20 in addition to being inserted into a stick. That is, the pipe itself is provided as a susceptor, and the pipe is induction heated by the induction coil (L ₁ ) provided with a gap therebetween, and the pipe heats the stick by contacting the outer surface of the stick inserted into the chamber 21-1. An aerosol may be generated by heating an aerosol-forming substrate provided therein.

Alternatively, the susceptor may be provided only in a pipe shape forming a wall surface of the chamber 21-1 of the holder 20 without a susceptor inserted into a stick. That is, the pipe itself is provided as a susceptor, and the pipe is induction heated by the induction coil (L ₁ ) provided with a gap therebetween, and the pipe heats the stick by contacting the outer surface of the stick inserted into the chamber 21-1. An aerosol may be generated by heating an aerosol-forming substrate provided therein.

Meanwhile, the holder 20 is inserted into the insertion space 11 of the cradle 10, and the TX coil 13 provided in the cradle 10 and the induction coil L1 functioning as the RX coil in the holder 20 wireless charging is carried out by The cradle 10 is provided with a large-capacity battery 12 and a control board 14 for controlling charging of the holder 20 . The TX coil is connected to the battery 12. In order for the user to charge the small-capacity battery 22 of the holder 20 to use the holder 20, the holder 20 is inserted into the insertion space 11 provided in the cradle 10 to perform wireless charging. .

At the bottom of the insertion space 11 of the cradle 10, there is a TX coil (TX antenna) 13 wound in a cylindrical shape outside the wall surface of the insertion space 11 to surround the insertion space 11, and the holder 20 ) is completely inserted into the insertion space 11, the induction coil L ₁ is located inside the wall surface of the holder 20 at the position of the holder 20 corresponding to the TX coil 13.

The TX coil 13 is provided by being wound in a cylindrical shape on the outside of the wall surface of the insertion space 11 to surround a predetermined height of the insertion space 11, and when the holder 20 is completely inserted into the insertion space 11, At a position corresponding to the height of the TX coil 13, an induction coil L ₁ is wound into a cylindrical shape similarly to the TX coil 13 and provided. Since both the TX coil 13 and the induction coil L ₁ are provided in a cylindrical shape, charging can be easily achieved by simply inserting the cylindrical holder 20 into the insertion space 11 . That is, since both the TX coil 13 and the induction coil L ₁ are wound in a cylindrical shape in a shape corresponding to each other by a height corresponding to a part of the height of the holder 20 along the longitudinal direction of the holder 20, the holder ( 20), there is no problem in charging even if inserted at any position along the circumferential direction.

After inserting the holder 20, charging may be started by pressing a button provided separately, or the insertion of the holder 20 may be detected by an appropriate sensor such as an optical sensor or a pressure sensor in the cradle 10, and the holder 20 may be inserted. It can be configured to start charging upon detecting the insertion of (20). If charging is started with only a separate button, there may be a problem in entering the charging mode even if the button is pressed incorrectly, so even if the button for charging is pressed, the charging mode is performed only when the sensor detects the insertion of the holder 20 can be configured to start. Alternatively, pressing the button may start the charging mode only when the insertion of the holder 20 is detected.

Alternatively, it is also possible to start the charging mode only when the insertion of the holder 20 is detected by the sensor described above without a physical button that may be accidentally pressed.

In addition, the holder 20 must be inserted so that the battery 22 is located upward. For this purpose, the shape of the inner surface of the insertion space 11 and the shape of the outer surface of the holder 20 correspond to each other, for example, the holder When inserting the upper end of the chamber 21-1 side of the chamber 21-1 side of the hole 20 upward, it may be inserted only up to a certain height in the upper part of the insertion space 11 and not inserted any further. That is, if the shape of the outer surface of the holder 20 is slightly larger from the upper part (chamber part) to the lower part (battery part), and the shape of the inner surface of the insertion space 11 of the cradle 10 is also formed correspondingly, the holder In order to completely insert the 20 into the insertion space 11, the upper part (chamber portion) of the holder 20 will have no choice but to be inserted downward.

In this way, when the holder 20 is inserted into the insertion space 11 of the cradle 10 so that the upper part (chamber portion) faces downward, the lower part (battery) of the holder 20 is inserted according to the insertion of the holder 20. Since the end of the part) closes the insertion space 11, a separate insertion space opening/closing structure may not be required in the cradle 10. That is, as the holder 20 is inserted, the insertion space 11 is closed, and the chamber 21-1 is completely accommodated in the insertion space 11, so such an opening and closing structure is not required.

Alternatively, in order to remove contaminants or foreign substances that may exist in the chamber 21-1 of the holder 20 in a state in which the holder 20 is completely inserted into the cradle 10 with the upper part (chamber portion) facing down. A cradle cover 15 may be formed on the cradle 10 . In this case, the user usually holds the cradle 10 in the direction shown in FIG. 1 and uses it. When the cradle cover 15 is opened, contaminants or foreign substances that may be present in the chamber 21-1 of the holder 20 This creates a situation where it is easy to be removed downward by gravity.

The embodiment according to FIG. 1 is characterized in that the induction coil (L ₁ ) functions as an RX coil during wireless charging and as an induction heating coil during induction heating. That is, when wireless charging is performed by inserting the holder 20 into the insertion space 11 of the cradle 10, the induction coil L ₁ functions as an RX coil to charge the small-capacity battery 22 of the holder 20. When the holder 20 is separated from the insertion space 11 of the cradle 10 and the stick is accommodated in the chamber 21-1 to heat the aerosol-forming material in the stick, the induction coil (L ₁ ) functions as an induction heating coil to apply an induction magnetic field to the susceptor having a pipe shape and/or a shape that can be inserted into a stick.

2 is a circuit block diagram of a holder for wireless charging according to a first embodiment of the present invention. 1 and 2, the wireless rechargeable aerosol generator according to the present invention includes an insertion space 11 into which a holder 20 is inserted, a battery 12, and a TX coil 13 connected to the battery 12. The holder 20 having a cradle 10 and an RX wireless charging block 24 and being inserted into the cradle 10 to charge the wireless power transmitted from the TX coil 13 provided in the cradle 10 However, the holder 20 is selectively connected to the chamber 21-1 into which the stick can be inserted, the heater driving unit 25, and the heater driving unit 25, and the resonant capacitor C ₁ and the induction coil L ₁ ) with an induction heating unit 26, a susceptor 21-2 induction heated by the induction heating unit 26, between the heater driving unit 25 and the induction heating unit 26, and RX wireless charging The first switch block 28-1 provided between the block 24 and the induction heating unit 26 and selectively switched, and provided between the induction heating unit 26 and the RX wireless charging block 24 for induction heating The connection between the resonance frequency adjusting means 27 for adjusting the resonance frequency to the wireless charging RX resonance frequency, the induction heating unit 26, the resonance frequency adjusting means 27, and the RX wireless charging block 24 is selectively switched. 2 includes a switch block 28-2 and a microcontroller 29 that controls the heater driver 25 and/or the first switch block 28-1 and/or the second switch block 28-2 . When a stick is inserted into the chamber 21-1 provided in the holder 20 and induction heating is performed, the microcontroller 29 is a first switch block provided between the heater driver 25 and the RX wireless charging block 24 By controlling (28-1), the heater driving unit 25 and the induction heating unit 26 are connected, and the susceptor 21-2 is induction heated by the induction heating unit 26. The microcontroller 29 is a heater A PWM signal is input to the driver 25, and power of a constant frequency is input to the resonance capacitor C ₁ and the induction coil L ₁ through the heater driver 25. At this time, the induction heating unit 26 and the resonant frequency adjusting unit 27 are not connected, and the induction heating resonant frequency f _h during induction heating is given by the following equation.

In addition, when wireless charging is performed by inserting the holder 20 into the cradle 10 for the purpose of charging, in general, the wireless charging RX resonance frequency is different from the induction heating resonance frequency, and according to the present invention, the induction coil L ₁ is set to RX When functioning as a coil, the induction heating resonance frequency must be adjusted to the wireless charging RX resonance frequency so that wireless charging can be performed with maximum efficiency. When the holder 20 is wirelessly charged, the microcontroller 29 controls the first switch block 28-1 so that the induction heating unit 26 is connected to the RX wireless charging block 24, and the second switch block 28-2 is controlled so that the induction heating unit 26, the resonant frequency adjusting unit 27, and the RX wireless charging block 24 are connected. In general, the wireless charging RX resonant frequency (fc) is given by the following equation.

Here, Lc is the total wireless charging inductance, and generally Lc is given by the following formula when the induction coil (Ls) is connected in series to the induction coil (L ₁ ).

In addition, when the induction coil Lp is connected in parallel to the induction coil L ₁ , the following equation is given.

In addition, here, Cc is the total wireless charging capacitance, and generally Cc is given by the following formula when the capacitor Cs is connected in series to the resonant capacitor C ₁ .

In addition, when the capacitor Cp is connected in parallel to the resonant capacitor C ₁ , it is given by the following equation.

If the induction heating resonance frequency is greater than the RX wireless resonance frequency, according to the embodiment, the resonance frequency adjusting means 27 is connected to the RX wireless charging block 24 and is connected to the induction coil L ₁ by the second switch block 28-2. ) is a resonant frequency control induction coil (L2) that can be connected in series to, where the second switch block 28-1 is provided between the induction coil (L ₁ ) and the resonant frequency control induction coil (L ₂ ). When the holder 20 is wirelessly charged, the microcontroller 29 controls the second switch block 28-2 so that the resonant frequency adjusting induction coil L ₂ is connected in series with the induction coil L ₁ . Therefore, the induction heating resonance frequency is reduced by the resonance frequency control induction coil (L ₂ ) and is adjusted to the wireless charging RX resonance frequency. Here, the wireless charging resonance frequency is a preset value, and accordingly, the inductance value of the resonance frequency adjusting induction coil (L ₂ ) can be designed to adjust to the wireless charging RX resonance frequency. According to the embodiment, the RX wireless charging block 24 includes a rectifier circuit for rectifying the wireless charging current into DC and a battery 22 for charging the DC current transmitted through the rectifier circuit.

3 is a circuit block diagram of a holder for wireless charging according to a second embodiment of the present invention. Referring to FIGS. 1 and 3, the resonant frequency adjusting means 27 is connected in parallel with the resonant capacitor C ₁ and can be connected to the RX wireless charging block 24 by the second switch block 28-2. A frequency control capacitor (C ₂ ), wherein the second switch block (28-2) is provided between the resonant frequency control capacitor (C ₂ ) and the RX wireless charging block 24, and the induction coil (L ₁₎ and the RX wireless charging Between the blocks 24, a third switch block 28-3 turned on and off under the control of the microcontroller 29 is included. When a stick is inserted into the chamber 21-1 provided in the holder 20 and induction heating is performed, the microcontroller 29 is a first switch block provided between the heater driver 25 and the RX wireless charging block 24 By controlling (28-1), the heater driving unit 25 and the induction heating unit 26 are connected, and the susceptor 21-2 is induction heated by the induction heating unit 26. At this time, the resonance frequency adjusting capacitor ( C ₂ ) and the induction coil (L ₁ ) are not connected to the RX wireless charging block 24, respectively. When wireless charging is performed by inserting the holder 20 into the cradle 10 for charging purposes, the microcontroller 29 controls the first switch block 28-1 so that the induction heating unit 26 is the RX wireless charging block ( 24), and controls the second switch block 28-2 so that the resonant capacitor C ₁ and the resonant frequency adjusting capacitor C ₂ connected in parallel are connected to the RX wireless charging block 24, The third switch block 28-3 is controlled to connect the induction coil L ₁ and the RX wireless charging block 24. Therefore, when the induction heating resonance frequency is greater than the wireless charging RX resonance frequency, the induction heating resonance frequency is reduced by the resonance frequency control capacitor (C ₂ ) and adjusted to the wireless charging RX resonance frequency. Here, the wireless charging resonance frequency is a preset value, and accordingly, the capacitance value of the resonance frequency control capacitor (C ₂ ) can be designed to adjust to the wireless charging RX resonance frequency.

4 is a circuit block diagram of a holder for wireless charging according to a third embodiment of the present invention. Referring to Figures 1 and 4, the resonant frequency adjusting means 27 is connected to the RX wireless charging block 24 and is connected in series to the induction coil L ₁ by the second switch block 28-2. A frequency control induction coil (L ₂ ), a resonant capacitor (C ₁ ) connected in parallel and a resonant frequency control capacitor (C ₂ ) that can be connected to the RX wireless charging block 24 by a second switch block (28-2) ), and the second switch block 28-2 is a switch block provided between the induction coil (L ₁ ) and the resonance frequency control induction coil (L ₂ ), the resonance frequency control capacitor (C ₂ ) and the RX wireless charging block. (24) each including a switch block provided between them. When a stick is inserted into the chamber 21-1 provided in the holder 20 and induction heating is performed, the microcontroller 29 is a first switch block provided between the heater driver 25 and the RX wireless charging block 24 By controlling (28-1), the heater driving unit 25 and the induction heating unit 26 are connected, and the susceptor 21-2 is induction heated by the induction heating unit 26. At this time, the induction heating unit 26 ) and the resonant frequency control induction coil (L ₂ ) are not connected, and the resonant frequency control capacitor (C ₂ ) is not connected to the RX wireless charging block 24. When wireless charging is performed by inserting the holder 20 into the cradle 10 for charging purposes, the microcontroller 29 controls the first switch block 28-1 so that the induction heating unit 26 is the RX wireless charging block ( 24), and controls the switch block provided between the induction coil (L ₁ ) of the second switch block (28-2) and the resonance frequency control induction coil (L ₂ ) to control the resonance frequency control induction coil (L ₂ ). ) is connected in series with the induction coil (L ₁ ), and controls the switch block provided between the resonant frequency adjusting capacitor (C ₂ ) of the second switch block (28-2) and the RX wireless charging block (24) The resonant capacitor (C ₁ ) and the resonant frequency adjusting capacitor (C ₂ ) connected in parallel are connected to the RX wireless charging block (24). Therefore, when the induction heating resonance frequency is greater than the wireless charging RX resonance frequency, the induction heating resonance frequency is reduced by the resonance frequency control induction coil (L ₂ ) and the resonance frequency control capacitor (C ₂ ) and is adjusted to the wireless charging RX resonance frequency. Here, the wireless charging resonance frequency is a preset value, and accordingly, the inductance value of the resonance frequency adjusting induction coil (L ₂ ) and the capacitance value of the resonance frequency adjusting capacitor (C ₂ ) can be designed to adjust to the wireless charging RX resonance frequency. .

5 is a circuit block diagram of a holder for wireless charging according to a fourth embodiment of the present invention. Referring to FIGS. 1 and 5, the resonant frequency adjusting means 27 is connected to the RX wireless charging block 24 and is connected to the induction coil L ₁ by the second switch block 28-2 and the resonance that can be connected in parallel. A frequency control induction coil (L ₂ ), where the second switch block (28-2) is provided between the induction coil (L ₁ ) and the RX wireless charging block (24). When a stick is inserted into the chamber 21-1 provided in the holder 20 and induction heating is performed, the microcontroller 29 is a first switch block provided between the heater driver 25 and the RX wireless charging block 24 By controlling (28-1), the heater driving unit 25 and the induction heating unit 26 are connected, and the susceptor 21-2 is induction heated by the induction heating unit 26. At this time, the induction coil (L ₁ ) is a state not connected to the RX wireless charging block 24. When wireless charging is performed by inserting the holder 20 into the cradle 10 for charging purposes, the microcontroller 29 controls the first switch block 28-1 so that the induction heating unit 26 is the RX wireless charging block ( 24), and by controlling the second switch block 28-2, the induction coil (L ₁ ) and the RX wireless charging block 24 are connected, and the induction coil (L ₁ ) and the resonant frequency adjusting induction coil ( L ₂ ) is connected in parallel. Therefore, when the induction heating resonance frequency is smaller than the wireless charging RX resonance frequency, the induction heating resonance frequency is increased by the resonance frequency adjusting induction coil (L ₂ ) and is adjusted to the wireless charging RX resonance frequency. Here, the wireless charging resonance frequency is a preset value, and accordingly, the inductance value of the resonance frequency adjusting induction coil (L ₂ ) can be designed to adjust to the wireless charging RX resonance frequency.

6 is a circuit block diagram of a holder for wireless charging according to a fifth embodiment of the present invention. Referring to FIGS. 1 and 6, the resonant frequency adjusting means 27 is connected in series with the resonant capacitor C ₁ and the resonant frequency that can be connected to the induction coil L ₁ by the second switch block 28-2. An adjustment capacitor (C ₂ ), where the second switch block (28-2) is between the resonance capacitor (C ₁ ) and the induction coil (L ₁ ) and between the resonance frequency adjustment capacitor (C ₂ ) and the induction coil (L ₁ ). It is provided in, and between the induction coil (L ₁ ) and the RX wireless charging block 24, a third switch block 28-3 turned on-off under the control of the microcontroller 29 is included. do. When a stick is inserted into the chamber 21-1 provided in the holder 20 and induction heating is performed, the microcontroller 29 is a first switch block provided between the heater driver 25 and the RX wireless charging block 24 By controlling (28-1), the heater driving unit 25 and the induction heating unit 26 are connected, and the susceptor 21-2 is induction heated by the induction heating unit 26. At this time, the resonant capacitor C ₁ ) is connected to the induction coil (L ₁ ), the resonant frequency control capacitor (C ₂ ) and the induction coil (L ₁ ) are not connected, and the induction coil (L ₁ ) and the RX wireless charging block 24 are also connected. It is not connected. When wireless charging is performed by inserting the holder 20 into the cradle 10 for charging purposes, the microcontroller 29 controls the first switch block 28-1 so that the induction heating unit 26 is the RX wireless charging block ( 24), and controls the second switch block 28-2 so that the resonance frequency adjusting capacitor (C ₂ ) connected in series with the resonance capacitor (C ₁ ) is connected to the induction coil (L ₁ ), 3 Controls the switch block 28-3 to connect the induction coil L ₁ and the RX wireless charging block 24. Therefore, when the induction heating resonance frequency is smaller than the wireless charging RX resonance frequency, the induction heating resonance frequency is increased by the resonance frequency control capacitor C ₂ and adjusted to the wireless charging RX resonance frequency. Here, the wireless charging resonance frequency is a preset value, and accordingly, the capacitance value of the resonance frequency control capacitor (C ₂ ) can be designed to adjust to the wireless charging RX resonance frequency.

7 is a circuit block diagram of a holder for wireless charging according to a sixth embodiment of the present invention. Referring to Figures 1 and 7, the resonant frequency adjusting means 27 is connected to the RX wireless charging block 24 and the second switch block 28-2 by the induction coil (L _One ) Resonance that can be connected in parallel A frequency control induction coil (L ₂ ) and a resonant capacitor (C ₁ ) are connected in series and can be connected to the induction coil (L ₁ ) by a second switch block (28-2) A resonant frequency control capacitor (C ₂ ) And, the second switch block 28-2 is a switch block provided between the induction coil (L ₁ ) and the RX wireless charging block 24, and the resonance capacitor (C ₁ ) and the induction coil (L ₁ ) between and resonance Each includes a switch block provided between the frequency control capacitor (C ₂ ) and the induction coil (L ₁ ). When a stick is inserted into the chamber 21-1 provided in the holder 20 and induction heating is performed, the microcontroller 29 is a first switch block provided between the heater driver 25 and the RX wireless charging block 24 By controlling (28-1), the heater driving unit 25 and the induction heating unit 26 are connected, and the stick is induction heated by the induction heating unit 26. At this time, the induction coil (L ₁ ) is the RX wireless charging block (24), the resonant capacitor (C ₁ ) is connected to the induction coil (L ₁ ), and the resonant frequency adjusting capacitor (C ₂ ) and the induction coil (L ₁ ) are not connected. When wireless charging is performed by inserting the holder 20 into the cradle 10 for charging purposes, the microcontroller 29 controls the first switch block 28-1 so that the induction heating unit 26 is the RX wireless charging block ( 24), and controls the switch block provided between the induction coil (L ₁ ) of the second switch block (28-2) and the RX wireless charging block (24) to charge the induction coil (L ₁ ) and the RX wireless charging The block 24 is connected and the induction coil (L ₁ ) and the resonant frequency control induction coil (L ₂ ) are connected in parallel. In addition, by controlling the switch block provided between the resonant capacitor (C ₁ ) and the induction coil (L ₁ ) of the second switch block (28-2) and between the resonant frequency adjusting capacitor (C ₂ ) and the induction coil (L ₁ ), A resonant frequency adjusting capacitor (C ₂ ) connected in series with the resonant capacitor (C ₁ ) is connected to the induction coil (L ₁ ). Therefore, when the induction heating resonance frequency is smaller than the wireless charging RX resonance frequency, the induction heating resonance frequency is increased by the resonance frequency adjusting induction coil (L ₂ ) and the resonance frequency adjusting capacitor (C ₂ ) and is adjusted to the wireless charging RX resonance frequency. Here, the wireless charging resonance frequency is a preset value, and accordingly, the inductance value of the resonance frequency adjusting induction coil (L ₂ ) and the capacitance value of the resonance frequency adjusting capacitor (C ₂ ) can be designed to adjust to the wireless charging RX resonance frequency. .

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes are within the scope of the claims.

Claims (8)

A cradle having an insertion space into which a holder is inserted, a battery, and a TX coil connected to the battery;
A holder having an RX wireless charging block and inserted into a cradle to charge wireless power transmitted from a TX coil provided in the cradle; including,
The holder includes a chamber into which a stick can be inserted;
a heater driver;
an induction heating unit selectively connected to the heater driving unit and having a resonant capacitor and an induction coil;
a susceptor induction heated by an induction heating unit;
a first switch block provided between the heater driver and the induction heating unit and between the RX wireless charging block and the induction heating unit to be selectively switched;
a resonant frequency adjusting means provided between the induction heating unit and the RX wireless charging block to adjust the induction heating resonant frequency to the wireless charging RX resonant frequency;
a second switch block for selectively switching the connection between the induction heating unit, the resonant frequency adjusting unit, and the RX wireless charging block;
A wireless chargeable aerosol generator comprising a; microcontroller for controlling the heater driver and/or the first switch block and/or the second switch block. According to claim 1
The resonant frequency adjusting unit is a resonant frequency adjusting induction coil connected to the RX wireless charging block and capable of being serially connected to the induction coil by a second switch block, wherein the second switch block is provided between the induction coil and the resonant frequency adjusting induction coil. A wireless rechargeable aerosol generator, characterized in that for. According to claim 1,
The resonant frequency adjusting means is a resonant frequency adjusting capacitor connected in parallel with the resonant capacitor and capable of being connected to the RX wireless charging block by a second switch block, wherein the second switch block is provided between the resonant frequency adjusting capacitor and the RX wireless charging block, , Between the induction coil and the RX wireless charging block, a wirelessly chargeable aerosol generator comprising a third switch block that is turned on-off under the control of a microcontroller. According to claim 1,
The resonance frequency control means is connected to the RX wireless charging block and is connected in parallel to the resonance frequency control induction coil that can be connected in series to the induction coil by the second switch block and the resonance capacitor and is connected to the RX wireless charging block by the second switch block. A resonant frequency control capacitor that can be connected to, and the second switch block includes a switch block provided between the induction coil and the resonant frequency control induction coil and a switch block provided between the resonant frequency control capacitor and the RX wireless charging block, respectively. A wireless rechargeable aerosol generator, characterized in that. According to claim 1,
The resonance frequency control means is a resonance frequency control induction coil connected to the RX wireless charging block and capable of being connected in parallel to the induction coil by a second switch block, wherein the second switch block is provided between the induction coil and the RX wireless charging block A wireless rechargeable aerosol generator, characterized in that. According to claim 1,
The resonant frequency adjusting means is a resonant frequency adjusting capacitor connected in series with the resonant capacitor and capable of being connected to the induction coil by a second switch block, wherein the second switch block is between the resonant capacitor and the induction coil and between the resonant frequency adjusting capacitor and the induction coil. It is provided between the induction coil and the RX wireless charging block, characterized in that it comprises a third switch block that is turned on-off by the control of the microcontroller. According to claim 1,
The resonant frequency control means is connected to the RX wireless charging block and is connected in series with the resonant frequency control induction coil that can be connected in parallel to the induction coil by the second switch block, and the resonance capacitor in series and connected to the induction coil by the second switch block. The second switch block is a switch block provided between the induction coil and the RX wireless charging block, and a switch block provided between the resonance capacitor and the induction coil and between the resonance frequency control capacitor and the induction coil, respectively. Wireless chargeable aerosol generator, characterized in that it comprises. According to any one of claims 1 to 7,
The RX wireless charging block is a wirelessly chargeable aerosol generator, characterized in that it includes a rectifier circuit and a battery.

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